Insecticidal and acaricidal composition and process for controlling pests

ABSTRACT

An insecticidal and acaricidal composition comprising a pesticidal amount of an interacted compound of a pyrethroid with a cyclodextrin and a diluent or carrier, and a process for controlling pests using said composition.

United States Patent [.191

Mifune et al.

[111 3,846,551 [451 Nov. 5, 1974 1 INSECTICIDAL AND ACARICIDAL COMPOSITION AND PROCESS FOR CONTROLLING PESTS [75] Inventors: Akira Mifune, Tokyo; Yoshio Katsuda, Nishinomiya; Toyoaki Yoneda, Tokyo, all of Japan [73] Assignees: Teijin Limited; Dai Nihon Jochugiku C0.-Ltd., both of Osaka, Japan [22] Filed: Nov. 16, 1973 [21] Applr No.: 416,666

[30] Foreign Application Priority Data Nov. 20, 1972 Japan 47-115678 s2 u.s.c|. ..424/180 51] int. c1. A0ln9/00,AO1n 9/28 Primary Examiner-Elbert L. Roberts Attorney, Agent, or FirmSherman & Shalloway [57] ABSTRACT An insecticidal and acaricidal composition comprising a pesticidal amount of an interacted compound of a pyrethroid with a cyclodextrin and a diluent or carrier, and a process for controlling pests using said composition.

5 Claims, No Drawings INSECTICIDAL AND ACARICIDAL-COMPOSITION AND PROCESS FOR CONTROLLING PESTS This invention relates to an insecticidal and acaricidal composition containing as an active ingredient an interacted compound (or molecular compound) of a pyrethroid with a cyclodextrin which contributes to the improvement of the stability of the pyrethroids to heat and light and exhibits insecticidal and acaricidal effects; and to a process for controlling pests.

Pyrethroids have been widely utilized because of their superior pesticidal effect and having substantially no toxicity or very low toxicity to man and other warmblooded animals, but on the other hand, have the defect of poor stability to heat and light, which poses a serious problem in storage for prolonged periods of time.

guest compound and the cyclodextrin as a host crystal,

has an improved pesticidal effect, such as rapid effectiveness, as compared with the pyrethroid alone as an active ingredient.

Accordingly, it is an object of this invention to pro vide an insecticidal and acaricidal composition having improved stability and pesticidal effects.

Another object of this invention is to provide a process'for controlling pests using the above interacted compound.

Many other objects of this invention along with its advantages will become more apparent from the following description.

The pyrethroids themselves to be'used for forming the active ingredient of the composition of this invention are known. Examples are pesticidal component pyrethrins of a natural source which arecontained in pyrethrum obtained for example, by drying the flower of Chrysanthemum cinerariaefolium, or synthetic pesticidal component Mimics. They are known to be esters of chrysanthemic acid or esters of chrysanthemum dicarboxylic acid. Specific examples of these natural and synthetic pyrethroids are:

l. Pyrethrins (natural):

R1 I I i I I U V \X coo t methyl or methoxycarbonyl pent-2,4-dienyl, Z-butenyl or 2-pentenyl 2. Mimics (synthetics):

2 R methyl or iso-butenyl R hydrogen or'methyl R allyl or propargyl A compound of formula [II] wherein R is isobutenyl, R is hydrogen, and R is allyl is well known as Allethrin.

mula [lI]] A compound of formula [III] wherein R is isobutenyl and R is hydrogen is well known as Tetramethrin.

[wherein R and R are the same as defined in formula [II], X is methyl, allyl, propargyl, benzyl or phenoxy, and n is l to 3, with the proviso that when n is 2, at least one X is methyl, and when n is 3, at least two Xs are methyl] Compounds of formula [IV] wherein R R and X respectively represent isobutenyl, hydrogen and 2,4- dimethyl (n=2), isobutenyl, hydrogen and S-phenoxy (n=l and isobutenyl, hydrogen and 4-allyl (n=l) are called respectively as Dimethrin, Phenothrin and Benathrin.

Re 1137A 4 3 [wherein R and R are the same as defined in formula [II], Z is S or -O, R is hydrogen,

methyl or C -3 alkyl, alkenyl, or alkynyl, Y is methyl, allyl, propargyl or benzyl, and m is l or 2,

with the proviso that when m is 2, at least one Y is methyl] Compounds of the formula [V] wherein Z is '-0--, and R R R and Y are isobutenyl, hydrogen, hydrogen and 2-benzyl (m=l) respectively, and isobutenyl, hydrogen, hydrogen and (2-propargyl, 5- methyl(m=2)respectively, are well known respectively as Resmethrin and Proparthrin.

[wherein R R R Y, Z and m are the same as defined in formulae [II] and [V]] [wherein R and R are the same as defined in for- C O O N i v i Butethl'in I 123W C O O l-allylindane-l-yl-ehrysanthemate The cyclodextrin itself to .be used for preparing the active component in the present invention is also known and often called cycloamylose or Schardinger dextrin. The cyclodextrin is a substance usually used,

for example, as a filler in a gas chromatographic column, or a carrier of medicines. It has a structure wherein the glucose units are cyclically bonded, and usually consists of about 6 to 8 glucose units. The method for its preparation is also well known, and for example, it can be prepared by the method disclosed in Die St'arke" 15, Nr. 8, page 281 (1963), which involves causing cyclodextrin glyeosyltransferase to act on starch or a hydrolyzed product ofstarchthereby to decompose and cleave the helical structure of the starch and to bond the cut ends. Furthermore, the cyclodextrin can be prepared by the method disclosed in Japanese Patent Publication No. 2380/71 which comprises causing amylase of Bacillus macerans to act on starch which has been lightly liquefied to a DE of not more than 15. The cyclodextrins available are, for example, a-cyclodextrin (cyclohexamylose), B-cyclodextrin (cycloheptamylose), and 'y-cyclodextrin (cyclooctamylose). Usually, they are obtained as a mixture of these, and can be separated and purified by, for example, fractional precipitation. 1n the present invention, they can be used either as a mixture or as separated individual compounds. I

The interacted compound of a pyrethroid with a cyclodextrin used an an active ingredient of the composition of this invention can be prepared by contacting at least one pyrethroid intimately with at least one cyclodextrin in the presence of water. The water may be adhered or added water which thepyrethroid and/or cyclodextrin can contain, but usually further water is added.

For example, it can -be prepared by sufficiently kneading 10 to 20 parts by weight of a pyrethroid, to 150 parts by weight of a cyclodextrin, and 30 to 60 parts by weight of water in a kneader (further adding a small amount of water if desired, when the viscosity of the mixture increases), pouring the kneaded mixture into five times its volume of water, and separating the precipitate by filtration and drying it to form a powdery product. The suitable temperature for kneading is about 5 to about 70C., preferably about 15 to 30C. Usually, the kneading is carried out for about 30 minutes to about 4 hours. Alternatively, a pyrethroid isadded to an aqueous solution of a cyclodextrin, and the mixture is stirred for 30 minutes to 4 hours. Then, the stirred mixture is allowed to stand'for 3 to 6 hours, followed by filtration and drying. The stirring temperature is about 5 to 70C., preferably about 30 to about 50C. The preferred temperature at the time of standing is room temperature or higher.

The interacted compound used as an active ingredient of the composition of the present invention has properties clearly different from those of a mere mixture of the pyrethroid and the cyclodextrin, and the inventors presume that it is an inclusion compound consisting of the pyrethroid as a guest compound and the cyclodextrin as a host crystal. The proportion of the pyrethroid to the cyclodextrin in the resulting interactedcompound may vary over a range of 0.5 to 1.5 mols per mol of the cyclodextrin.

When an interacted compound consisting of 1 mol of allethrin as the pyrethroid per mol of the cyclodextrin is washed with cold water, no pyrethroid is washed out, but when said interacted compound is extracted with diethyl either for 24 hours using a Soxhlet extractor, 0.5 mol of pyrethroid remains in the interacted compound per mol of the cyclodextrin, and the pyrethroid cannot be extracted further. It has not yet been clarified in what form 0.5 mol of the extracted pyrethroid is included, connected, or merely adhered in the rings and/or among the rings of the cyclodextrin. However, in view of the fact that when a mere mixture of the pyrethroid and the cyclodextrin is extracted similarly, J substantially all of the pyrethroid is extracted, it is evident that some interaction occurs between the two compounds in the active ingredient used in this in view of the fact that the cyclodextrin is known to form an inclusion compound with, for example, menthyl acetate, we presume that probably an inclusion compound consisting of the cyclodextrin as a host crystal and the pyrethroid as a guest compound is formed.

Stability to ultraviolet rays was tested using an ultraviolet ray lamp (254 mp.) as an irradiation source on interacted compounds of this invention in which allethrin is present in a proportion of 0.5 mol per mol of cyclodextrin and ma proportion of 1.0 mol per. mol of cyclodextrin, a mere mixture of 1 mol of cyclodextrin and 0.5 mol of allethrin (Control No. l), and a mere mixture of lmol of starch and 0.5 mol of allethrin (Control No. 2). The results are shown in the following table 1. 1n the table, CD stands for cyclodextrin, and Alle stands for allethrin. The numerical values show the amounts of residue. The numerical values in the parentheses are the rate of residue in percent with the value at the start being percent.

invention. Furthermore,

Table 1 Sample Irradiation time Start l weeks 2 weeks 3 weeks This CD-Allc 110.5 invention interacted com- 10.90% 10.06% 8.15% 6.78%

Ound 100) (92.3) (74.8) (62.2) CD-Alle 1:1 interacted 16.65% 12.55% 10.00% v 8.42% compound (100) (75.5) (60.0) (50.5) Control CD-Alle mixture 7.80 2.28 O 0 N6. 1 100 29.2 0 (0 Control Starch-Alla 8.45 3.82 0.8 0 No.2 mixture (100 45.2) 9.5 o

The 1rrad1at1on source an ultraviolet ray lamp Examples of the surface active agent or emulsifier are It is also seen from the results of Table 1 that interaction occurs between the cyclodextrin and the pyrethroid in the active ingredient used in the present invention, to increase stability to ultraviolet rays, and the active ingredient used in this invention differs from a mere mixture of these two compounds. The results of the ultraviolet ray stability test and the extraction test show that the active ingredient used in this invention differs from the mere mixture, but is presumed to be the inclusion compound mentioned above.

Since, as stated above, the active ingredient used in this invention can be formed by contacting at least one pyrethroid intimately with at least one cyclodextrin in the presence of water, it will be readily understood that depending upon the formulation, the interacted product can be formed at the time of preparing the final pesticidal composition instead of preparing the interacted product in advance and then blending it with a diluent or carrier. For instance, in the case of a wettable powder, the interacted product can be formed during its preparation.

The insecticidal and acaricidal composition of this invention may be in various formulations, such as a liquid, emulsifiable concentrate, wettable powder, oil, aerosol, paste, fumigant, dust, granule, tablet, or pellet.

The insecticidal and acaricidal composition of this invention contains various gaseous, liquid or solid diluents or carriers, and if desired, may be further contain various assistants, such as a'surface active agent, emulsifier, dispersing agent, spreader, sticker, synergist, antioxidant, ultraviolet absorbent, and other insecticide.

ane, alcohols such as methanol, ethanol, propanol, or

butanol, keytones such as acetone, methyl ethyl ketone, or cyclohexanone, and water. Examples of the anionic surfactants such as a sodium alkylbenzenesulfonate, sodium stearate, sodium lauryl sulfate, a butylamine salt of dodecylbenzenesulfonic acid, an alkylphenolsulfonic acid salt, or a ligninsulfonic acid salt, and nonionic surfactants such as an ester of tall oil, polyoxyethylene nonylphenylether, a polyoxyethylene fatty acid ester, a polyoxyethylene alkylaryl ether, or a polyoxyethylene ether of a polyhydric alcohol.

Examples of the dispersing agents are an alkylcellulose lignin sulfite spent liquor, sodium dioctylsulfosuccinate, sodium dibutylphenylphenol disulfonate, sodium dodecylbenzene sulfonate, sodium lauryl sulfate, polyethylene glycol oleate, a tall oil ester of polyethylene glycol, and p-isooctylphenol decaethylene glycol ether.

Examples of the synergist are piperonyl butoxide, octachlorodipropyl ether, N-(2-ethylhexyl)- bicyclo[ 2 ,2,l]- hepta-S-ene 2,3-dicarboxiimide, N- octylsulfoxide of isosafrole, isoborayr thiocyanoacetate, and B-butoxy-B'-thiocyano diethyl ether. iso- .bornyl may be cited as another insecticide. type The insecticidal and acaricidal composition of this invention contains a pesticidal amount of the interacted compound of a pyrethroid with a cyclodextrin in an amount of, for example, 0.5to 100 percent by weight. The content of this active ingredient varies depending upon, for example, the formulation, the method of application, the type of the pest, and time and place of application.

The composition of this invention can be applied to pests and/or their habitat by various means such as spraying, atomizing, misting, dust spraying, fumigating, or irrigation.

The amount of the interacted compound in the ready-to-use preparation can be varied over a wide range according to the formulation. Generally, it is about 0.01 to 50 percent by weight.

The insecticidal and acaricidal composition of this invention is useful for controlling various pests such as sucking insects, biting insects, nematodes, other plant pests, sanitary pests, grain pests, agricultural pests, and

forest pests. Thus, the term insecticidal and acaricidal composition denotes a composition which is effective for controlling not only insects and acari but also nematodes. Specifically, the composition of this invention is useful for controlling coleopterous, lepidopterous, he-

solid diluent or carrier include mineral powders such as mipterous, orthopterous, isopterous and dipterous insects, and also acari and nematodes. These pests include not only imagoes, but also the larvae, pupae, and eggs thereof. Specific examples of these pests include flies, mosquitoes, cockroaches, fleas, louse, bedbugs, acari (Ornithonyssus bacoti, Dermanyssus gallinae, Or-

pyrethroid with a cyclodextrin is not a mere mixture of the pyrethroid and the cyclodextrin, and this was demonstrated by the test involving extractions with ether. In addition to this, the results of a supporting example based on thin-laayer chromatography are shown below. An interacted compound of allethrin with B-cyclodextrin (the molar ratio of the allethrin to the B-cyclodextrin being 1 2) was subjected to thin-layer chromatography [solvent acetone/wate1"=6/4, plate: Microcrystalline Cellulose (Eastmann C0,) 5 X 10 cm, color: 1 vapor], and its R; value and the number of spots were measured. The results are shown in the following table. As controls, allethrin, B-cyclodextrin, and a mixture of allethrin and B-cyclodextrin were used respectively.

Tested compounds Number R, value spots lnteructed compound of allethrin with fl-cyclodextrin 1 0.43 0.65 (yellow) Mere mixture of allethrin with B- 2 0.43 0.65 (yellow) cyclodextrin 0.97 1.00 (brown) Allethrin l 0.85 1.00 (brown) fl-Cyclodextrin l 0.42 0.65 (yellow) In the above table under the headline Compounds tested, the term interacted compounds denotes an interacted compound of a pyrethroid with B-cyclodextrin, and the term mixture, a mere mixture of a pyrethroid with B-cyclodextrin. The infrared spectra of the interacted compounds which occupy the spots on the thin-layer chromatogram are almost identical with those of the pyrethroid and B-cyclodextrin superposed on each other, and also correspond with those of the mere mixtures.

The following Examples illustrate the present invention in greater detail.

FORMULATION EXAMPLE 1 96g of diatomaceous earth was added to 4g ofan'interacted compound of resmethrin and B-cyclodextrin (25 percent by weight as resmethrin), and they were throughly stirred and mixed in a kneader to form dusts.

FORMULATION EXAMPLE 2 30 percent by weight of an interacted compound of tetramethrin and B- wbdextri (ZQPQ FW y we ht as tetramethrin) was well mixed with 10 parts of butyl amine salt of dodecylbenzene sulfonic acid and parts by weight of 300-mesh talc was added. They were mixed well in a kneader with stirring to form a wettable powder.

FORMULATION EXAMPLE 3 2g of an interacted compound of allethrin and B-cyclodextrin (25 percent by weight as allethrin), 1.5g of a synergist MGK-5026 (trademark for a mixture of N- octyl-bicycloheptenedicarboximide and an isopropylamine saltof dodecylbenzenesuIfonic acid), and 965g of a mosquito coil base consisting of pyrethrum extracted dust, wood dust and starch were uniformly mixed and formed into a mosquito coil by'a conventional method.

Pyrethroids Compounds tested Num R, values ber of spots Resmethrin B-cycl0dextrin l 0.42 0.69 (yellow) lnteracted compound l 0.41 0.65 (yellow) Mixture 2 0.51 0.64 (yellow) 0.7] 0.90 (brown) Resmethrin l 0.69 0.89 (brown) Furamethrin BCyelodextrin l 0.37 0.60 (yellow) interacted compound 1 0.36 0.60 (yellow) Mixture 2 0.42 0.61 (yellow) 0.91 0.99 (brown) Furamethrin l 0.86 0.98 (brown) Tetramethrin fl-cyclodextrin I l 0.41 0.63 (yellow) lnteracted compound 1 0.46 0.63 (yellow) Mixture 2 0.43 0.61 (yellow) 0.92 1.00 (brown) tetrumethrin l 0.87 1.00 (brown) Proparthrin fl-cyelodcxtrin l 0.31 0.65 (yellow) lnteracted compound 1 0.33 0.62 (yellow) Mixture 2 0.31 0.64 (yellow) 0.94 1.00 (brown) Propztrthrin 1 0.87 1.00 (brown) S-Propurgyl- Bcyclodextrin 1 0.41 0.64 (yellow) u-cthynyl-Z- Iurylmethyllnteracted compound l 0.37 0.59 (yellow) chrysanthcmute Mixture 2 0.37 0.58 (yellow) 0.93 1.00 (brown) 0.92 1.00 (brown) FORMULATION EXAMPLE 70 parts by weight of 300-mesh diatornaceous earth was added to 30 parts by weight of an interacted compound of pyrethrin (pyrethrum extract powder) and B-cyclodextrin (1 percent by weight as pyrethrum extract powder), and they were thoroughly mixed and stirred in a kneader to form a dust.

FORMULATION EXAMPLE 6 5g of an interacted compound of proparthrin and B-cyclodextrin (20 percent by weight as proparthrin) was well mixed with 5g of white petrolactum. 30 ml. of

water was added to the mixture, and they were well kneaded to form a paste-like insecticide.

About 5g of this insecticide was placed on a heater heated at 120 150C. to volatilize the proparthrin, and the resulting paste-like insecticide was used as an electric mosquito coil.

FORMULATION EXAMPLE 7 4g of an interacted compound of furamethrin and fi-cyclodextrin (20 percent by weightas furamethrin), 1.5g of piperonyl butoxide (synergist), 6g of stearic acid, 4.5g of Span 60 (nonionic surfactant) and 2.5g of Tween 60 (nonionic surfactant) were well mixed, and

- 31.5g of water was added to the mixture. They were well kneaded to form a paste.

About 5g of this paste was placed on a heater held at 120 to 150C. to volatilize the furamethrin, and the resulting product was used as an electrical mosquito coil.

FORMULATION EXAMPLE 8 4g of an interacted compound of proparthrin and.

a-cyclodextrin (15 percent by weight as proparthrin) and lg of a mixture of N-ectylbicycloheptenedicarboximide and an isopropyl amine salt of dodecylbenzenesulfonic acid (trademark, MGK-5026) were uniformly mixed with 95g of a mosquito coil base, and the mixture'was made into a mosquito coil by a conventional method.

FORMULATION EXAMPLE 9 A 98g of diatomaceous earth was added to 2g of an interacted compound of rethmethrin (15 percent by weight as proparthrin), and they were well stirred and mixed in a kneader to form a dust.

FORMULATION EXAMPLE 10 Seven interacted compounds v'vrpreisartifrarh tetramethrin, dimethrin, phenothrin, butethrin, 4- allylindane- 1 -y l -chrysanthemate, benathrin and a-ally- 1-5-propargyl-3-furylmethyl-chrysanthemate using B-cyclodextrin as a host crystal, and a dust containing each of these compounds as an active ingredient was prepared.

FORMULATION EXAMPLE 11 V Three interacted compounds (25 percent by weight as pyrethroid) were prepared from allethrin, japothrin,

and 5-propargyl-a-ehtynyl-2-furyl-methyl chrysanthemate using B-cyclodextrin as a host crystal, and a mosquito coil was prepared from 2g of each of these compounds and 98g of a mosquito coil base.

- FORMULATION EXAMPLE 12 g of an interacted compound of tetramethrin and 'y-cyclodextrin (15 percent by weight as tetramethrin), 51 g of sodium ligninsulfonate, 5g of a butylamine salt of dodecylbenzenesulfonic acid, and 10g of clay weresufficiently stirred and mixed to form a wettable powder.

FORMULATION EXAMPLE 13 g of an interacted compound of phenothrin and y-cyclodextrin and 10g of p-isooctylphenoldecaethylene glycol ether were well stirred and mixed by a kneader to form a wettable powderf PEST CONTROL EXAMPLE 1 Using interacted compounds of various pyrethroids indicated in Table 3 below and cyclodextrin, mosquito coils containing 0.5 percent by weight of pyrethroids were prepared in accordance with Formulation Examples 3, 4 and 8. Using these mosquito coils a testwas conducted to knock down imagoes of house mosquitoes. The test procedure was one disclosed at page 176 of Vol. 16 of the Japanese-language publication Bochu-Kagaku" (or Pest Control Science), 1951, page 176 and suggested by Nagasawa and Katsude. The relative effectiveness of the abovemosquito coils were calculated. The results are shown in Table 3.

- Table 3 Pyrethroid 16% 50% 84% Compound knock down knock down knock down Allethrin 1.09 (1.00) g 1.12 (1.00) 1.13 (1.00) Pyrethrin 1.l8(1.09) l.22(1.l4) 1.25(l.18) Furamethrin 2.46 (2.29) 2.51 (2.35) 2.58 (2.40) Proparthrin 2.23 (2.10) 2.27 (2.14) 2.31 (2.20)

The numbers in the table show the relative effectiveness of the interacted compounds, and those in the parentheses show the relative effectiveness of the pyrethroid alone.

EXAMPLE 2 Dusts containing 1 percent by weight of a pyrethroid as an effective ingredient were prepared in the same manner as in Formulation Examples 1 and 5 using various interacted compounds shown in Table 4. The resulting dusts were sprayed on a plywood at a rate of 8 g/m, and German cockroaches were brought into contact with the dusts for 5 minutes. The time required for 50 percent knockdown and the rate of dead cockroaches after a lapse, of 24 hours were measured. The results are shown in Table 4.

- 50 seconds It is surprising to note from the above results of experiment that the insecticidal effect is superior when the interacted compound containing pyrethroid is used thanwhen the pyrethroid is used alone.

Decomposition Test:-

lnteracted compounds of various pyrethroids and cyclodextrin (molar ratio of the cyclodextrin to the pyrethroid being 2 1 and pyrethroids alone were exposed to the irradiation of ultraviolet rays for 60 hours, and respectively by gas-chromatographic analysis, the amount of the pyrethroid decomposed was measured. The rate of decomposition was measured from the amount of decomposition determined. The results are shown in Table 5.

It is seen from the results obtained that pyrethroids which are weak in resistance to ultraviolet rays have gained stability to ultraviolet rays by about tenfold.

PEST CONTROL EXAMPLE 3 The same insecticidal test as in Pest Control Example 1 using the seven mosquito coils prepared in Formulation Example 11 and in accordancewith Formulation Example 1 1. The results are shown in Table 6.

Table 6 I 5 The figures in the parentheses show the relative effectiveness of the pyrethroids used alone.

PEST CONTROL EXAMPLE 4 The effects of the seven dusts prepared in F ormulation Example 10 against houseflies and acaridia were tested. 100 mg of each of the dusts was spread uniformly on a filter paper placed in a Petri dish having an inside diameter of 9 cm and a height of 6 cm. Ten each of'female and male houseflies and 10 acaridias were let free so to be in contact with the dust spread. for 60 minutes. The number of the dead after a lapse of 24 hours was observed. The test was conducted indoors, and the temperature of the room at the time was 24 to 28C. The results are shown in Table 7.

mate

The figures given in the parentheses show the rate of dead pestswhen the pyrethroid alone was applied.

PEST CONTROL EXAMPLE 5 Each of the wettable powders of Formulation Example 2 and Formulation Example 13 were applied to Chinese cabbages grown in pots on which 4th-instar larvae of white butterflies lived. The results are shown in Table 8.

Z-methylcyclopenta- 2-ene-4-one-1-yl 2,2,3 ,3-tetramcthylcyclopropane carboxylate 2,6-dimethyl-4-allylbenzyl 2,2,3-trimethylcyclopropane curboxylate 4-propargy1benzyl 2.2.3.3-tetrumethyl- 1.41 1.30) cyclopropanc carboxylate a-methyl-5-propargyl2- furylmcthyl 2,2,3-trime thylcyclopropane carboxylate 84% knockdown Ourmob

ammo

Example 13) The figures in the parentheses show the rate of dead larvae when the pyrethroid alone was applied.

PEST CONTROL EXAMPLE 6 A stomach poison test on houseflies was performed using an interacted compound of bio-allethrin and B-cyclodextrln (the molar ratio of the bio-allethrin to the B-cyclodextrin being 1 2).

Twenty houseflies (male and female) of the Takatsuki strain after four days from emergencewere used in each of the following four kinds of test.

a. 90 mg of sugar powder and absorbent cotton impregnated with about 2 ml. of water were used.

b. 90 mg of a mixture of sugar powder and ,8-cyclodextrin in a weight ratio of about 1:1, and about 2 ml. of water impregnated with water were used.

c. 90 mg of an interacted compound and bioallethrin and ,B-cyclodextrin were'used.

d. 90 mg of a mixture of the above interacted C01 pound and sugar in a weight ratio of about 1:1, and absorbent cottonimpregnated with about-2 ml. of water were used.

In each case observation was made after 40 minutes 35 10 cm long about 2 g) were used either the mm- 80 minute; 210 minutes and 1280 minutes The treated state or as treated with B-cyclodextrin, pyreresults (the number of dead houseflies) are sh throid and the above interacted compounds respecin Table 9 tively. The results (the number of dead pests) are 1 shown in Table 10. In the Table, the figures in the pa- Table 9 40 rentheses show the percentage of the remaining pine leaves. H g H H a l Tllme tdhflt b 80 2m 1280 It is seen from the results obtained that both of biominutes minutes minums minmes. allethrin and bio-resmethrin have much the same stom- C ach poison effect even when used as an interacted com- (a) 1 l l l 45 pound with B-cyclodextrin. b 1 i 1 In all cases, the rateof dead insects is low at the ini- 3 f2 :3 i8 tial stage when the interacted compounds of pyrethroids are used. But after a lapse of as long as 76 hour- Table 10' Amount of the pyrethrold' 0.1% by weight 0.02% by weight attached to the leaves Time t hat elapse Minutes Hours Minutes Hours Treating i agent for i No. pine tree leaves 10 70 225 21 76 10 20 22s 21 30 so 76 lnteractcd compound of y l bio-allethrin with 2 4 7 -6 7 7 7. s 0 2 3 4 4 5 5 7 B-cyclodextrin (ca. 100) (ca. interacted compound of 2 bio-resmethrin with 0 0 0 0 5 6 8 8 0 0 0 0 3 6 6 6 B-cyclodextrin (ca. (ca. 90) 3 Bio-allethrin 4 5 7 6 8 8 8 8 (ca. 90) 4 Bio-resmethrin 6 6 6 6 8 8 8 8 g (ca. 90) 5 The leaves not treated 0 0 0 0 l 1 l l (ca. 30) 6 Cyclodextrin alone 0 0 0 0 0 0 0 It is seen from the results obtained that cyclodextrin does not show stomach poison, and bio-allethrin exhibits good stomach poison even when used as an interacted compound with cyclodextrin.

The fact that the number of dead houseflies in case (d) is smaller than in case (d) at the initial stage is considered due to the fact that the concentration of the interacted compound was diluted as a result of dilution with sugar. Similar results were observed when an interacted compound of B-cyclodextrin with bioresmethrin, biotetramethrin, or furamethrin was used.

PEST CONTROL EXAMPLE 7 A stomach poison test was conducted on pine caterpillers using an interacted compound of bio-allethrin and B-cyclodextrin, and an interacted compound of biore'smethrin and B-cyclodextrin (in eachcase, the molar ratio of pyrethroid to B-cyclodextrin was 1:2).

In each test, eight 4th-instar larvae of pine caterpillars (body length 2 to 2.5 cm) were used. Six kinds of test were conducted. in each test, 40 pine leaves (8 Table 10 Continued Amount of the pyrethroid 0.004 by weight attached to the leaves Time that elapsed Minutes hours Treating agent for 7 No. pine tree leaves 10 70 225 21 50 76 l lnteracted compound of bio-allethrin with l l l l l l 2 2 B-cyclodextrin (co. 75) lnteracted compound 2 of bio-resmethrin with 0 0 0 '0 2 4 7 8 fl-cyclodextrin (ca. 80)

3 Bio-allethrin 4 Bio-resmethrin 5, there is heardly any difference in the rate of dead insects.

When using pine leaves to which a pyrethroid as an interacted compound of pyrethroid with B-cyclodextrin had been adhered, the pine caterpillars fell off from the P a e and wbw e tabe Lin o!!! sm h floor, although not to death. Accordingly, the pine caterpillars which ate the pyrethroid first fell from the pine leaves, and gradually die, and in view of this, the amount of the pine leaves eaten is very small irrespective of the time duration required before death, and the damage can be minimized.

Since pyrethroids have poor stability to ultraviolet rays, even if they are used as a mixture with starch, etc. as shown in Table 1, they lose their effect. But when used as interacted compounds with cyclodextrins, the pyrethroids become very stable to ultraviolet rays, and are scarcely decomposed for a prolonged period of time. This is especially advantageous for outdoor application of the pesticidal composition of this invention, as in the case of controlling the pine catapillars. Furthermore, thisdemonstrates that pyrethroids can be very effectively utilized by using them as interacted compounds with cyclodextrins.

What we claim is:

1. An insecticidal and acaricidal composition comprising a pesticidal amount of an interacted compound of a pyrethroid with a cyclodextrin and a diluent or carrler.

2. The composition of claim 1 wherein the amount of the interacted compound is 0.5 to percent by weight.

3. The composition of claim 1 wherein the amount of the pyrethroid in the interacted compound is 0.5 to 1.5 moles per mol of said cyclodextrin.

4. The composition of claim 1 wherein said cyclodextrin is a cyclodextrin consisting of 6 to 8 glucose molecule units.

5. A process for controlling pests which comprises applying a pesticidal amount of an interacted compound of a pyrethroid with a'cyclodextrin to pests and- /or their habitat. 

1. AN INSECTICIDAL AND ACARICIDAL COMPOSITION COMPRISING A PESTICIDAL AMOUNT OF AN INTERACTED COMPOUND OF A PYRETHROID WITH A CYCLODEXTRIN AND A DILUENT OR CARRIER.
 2. The composition of claim 1 wherein the amount of the interacted compound is 0.5 to 100 percent by weight.
 3. The composition of claim 1 wherein the amount of the pyrethroid in the interacted compound is 0.5 to 1.5 moles per mol of said cyclodextrin.
 4. The composition of claim 1 wherein said cyclodextrin is a cyclodextrin consisting of 6 to 8 glucose molecule units.
 5. A process for controlling pests which comprises applying a pesticidal amount of an interacted compound of a pyrethroid with a cyclodextrin to pests and/or their habitat. 